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Room-Temperature Antiferroelectricity in Multiferroic Hexagonal Rare-Earth Ferrites

Jun Younes Louhi Kasahara, Tsukasa Katayama, Shishin Mo, Akira Chikamatsu, Yosuke Hamasaki, Shintaro Yasui, Mitsuru Itoh, Tetsuya Hasegawa

2021ACS Applied Materials & Interfaces21 citationsDOI

Abstract

The antiferroelectric (AFE) phase, in which nonpolar and polar states are switchable by an electric field, is a recent discovery in promising multiferroics of hexagonal rare-earth manganites (ferrites), h-RMn(Fe)O3. However, this phase has so far only been observed at 60–160 K, which restricts key investigations into the microstructures and magnetoelectric behaviors. Herein, we report the successful expansion of the AFE temperature range (10–300 K) by preparing h-DyFeO3 films through epitaxial stabilization. Room-temperature scanning transmission electron microscopy reveals that the AFE phase originates from a nanomosaic structure comprising AFE P3̅c1 and ferroelectric P63cm domains with small domain sizes of 1–10 nm. The nanomosaic structure is stabilized by a low c/a ratio derived from the large ionic radius of Dy3+. Furthermore, weak ferromagnetism and magnetocapacitance behaviors are observed. Below 10 K, the film exhibits an M-shaped magnetocapacitance versus magnetic field curve, indicating unusual magnetoelectric coupling in the AFE phase.

Topics & Concepts

MagnetocapacitanceMultiferroicsMaterials scienceFerroelectricityAntiferroelectricityIonic radiusCondensed matter physicsPhase (matter)FerromagnetismDielectricOptoelectronicsIonPhysicsQuantum mechanicsMultiferroics and related materialsFerroelectric and Piezoelectric MaterialsAdvanced Condensed Matter Physics
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